Mathematical modeling and determination of thermodynamic properties of jabuticaba peel during the drying process

Costa, Cristian F.; Corrêa, Paulo C.; Vanegas, Jaime D. B.; Baptestini, Fernanda M.; Campos, Renata C.; Fernandes, Lara S.

doi:10.1590/1807-1929/agriambi.v20n6p576-580

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Sumário

STORAGE AND PROCESSING OF AGRICULTURAL PRODUCTS • Rev. bras. eng. agríc. ambient. 20 (6) • June 2016 • https://doi.org/10.1590/1807-1929/agriambi.v20n6p576-580 copy

Mathematical modeling and determination of thermodynamic properties of jabuticaba peel during the drying process

Modelagem matemática e propriedades termodinâmicas da casca da jabuticaba durante o processo de secagem

Authorship SCIMAGO INSTITUTIONS RANKINGS

ABSTRACT

Jabuticaba is a fruit native of Brazil and, besides containing many nutritional qualities, it also has a good field for use in products such as flour for cakes and biscuits, juice, liqueur, jelly and others. This study aimed to model the drying kinetics and determine the thermodynamic properties of jabuticaba peel at different drying air temperatures. Ripe fruits of jabuticaba (Myrciaria jaboticaba) were collected and pulped manually. Drying was carried out in a forced-air circulation oven with a flow of 5.6 m s^-1 at temperatures of 40, 50, 60 and 70 °C. Six mathematical models commonly used to represent the drying process of agricultural products were fitted to the experimental data. The Arrhenius model was used to represent the drying constant as a function of temperature. The Midilli model showed the best fit to the experimental data of drying. The drying constant increased with the increment in drying temperature and promoted an activation energy of 37.29 kJ mol^-1. Enthalpy and Gibbs free energy decreased with the increase in drying temperature, while entropy decreased and was negative.

Key words:
Myrciaria jaboticaba; enthalpy; entropy

Model designation	Model	Eq.
Approximation of diffusion	MR = a exp(–kt) + (1 – a) exp(–kbt)	(2)
Two-term	MR = a exp(–kt) + b exp(–ct)	(3)
Verma	MR = a exp(–kt) + (1 – a) exp(–bt)	(4)
Midilli	MR = a exp(–kt^c) + bt	(5)
Logarithmic	MR = a exp(–kt) + b	(6)
Page	MR = exp(–kt^c)	(7)

Models	R²	P (%)	SE	R²	P (%)	SE
	Temperature 40 °C			Temperature 50 °C
Approximation of diffusion	0.9991	3.267	0.012	0.9989	6.433	0.013
Two-term	0.9991	3.267	0.012	0.9993	4.376	0.011
Logarithmic	0.9991	3.771	0.012	0.9994	6.033	0.010
Midilli	0.9999	1.512	0.004	0.9998	1.804	0.005
Page	0.9994	4.569	0.009	0.9997	5.602	0.007
Vermaet al.	0.9991	3.267	0.012	0.9993	4.376	0.011
	Temperature 60 °C			Temperature 70 °C
Approximation of diffusion	0.9970	19.912	0.023	0.9970	20.290	0.023
Two-term	0.9980	11.823	0.018	0.9980	13.412	0.019
Logarithmic	0.9983	22.951	0.017	0.9984	20.675	0.017
Midilli	0.9999	7.548	0.004	0.9999	2.861	0.002
Page	0.9998	16.977	0.006	0.9998	13.032	0.005
Verma et al.	0.9980	11.825	0.018	0.9980	13.411	0.019

Temperatur e (°C)	Midilli	R²
40	MR = 0.9899 exp(–0.2194t^1.1654)+ 0.0036t	0.9998
50	MR = 0.9937 exp(–0.4021t^1.1183)+ 0.0018t	0.9998
60	MR = 0.9986 exp(–0.6548t^1.2034)+ 0.0016t	0.9999
70	MR =1.0024 exp(–0.7673^1.1994)+ 0.0019t	0.9999

Temperature (°C)	ΔH (J moL^-1)	ΔS (J moL^-1 K-1)	ΔG (J moL^-1)
40	34743.60	-65.91	34809.51
50	34662.29	-66.16	34728.45
60	34580.97	-66.41	34647.39
70	34499.66	-66.65	34566.31

Unidade Acadêmica de Engenharia Agrícola Unidade Acadêmica de Engenharia Agrícola, UFCG, Av. Aprígio Veloso 882, Bodocongó, Bloco CM, 1º andar, CEP 58429-140, Campina Grande, PB, Brasil, Tel. +55 83 2101 1056 - Campina Grande - PB - Brazil
E-mail: revistagriambi@gmail.com

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[1] cristianfernandescosta@gmail.com (Corresponding author)